GeneralizedUnivariatePowerSeries(Coef, Expon, var, cen)¶
genser.spad line 192 [edit on github]
Coef: Ring
Expon: Join(OrderedAbelianMonoid, SemiRing)
var: Symbol
cen: Coef
Author: Waldek Hebisch
- 0: %
from AbelianMonoid
- 1: %
from MagmaWithUnit
- *: (%, %) -> %
from Magma
- *: (%, Coef) -> %
from RightModule Coef
- *: (%, Fraction Integer) -> % if Coef has Algebra Fraction Integer
from RightModule Fraction Integer
- *: (Coef, %) -> %
from LeftModule Coef
- *: (Fraction Integer, %) -> % if Coef has Algebra Fraction Integer
from LeftModule Fraction Integer
- *: (Integer, %) -> %
from AbelianGroup
- *: (NonNegativeInteger, %) -> %
from AbelianMonoid
- *: (PositiveInteger, %) -> %
from AbelianSemiGroup
- +: (%, %) -> %
from AbelianSemiGroup
- -: % -> %
from AbelianGroup
- -: (%, %) -> %
from AbelianGroup
- /: (%, %) -> % if Expon has AbelianGroup and Coef has Field
from Field
- /: (%, Coef) -> % if Coef has Field
from AbelianMonoidRing(Coef, Expon)
- ^: (%, %) -> % if Coef has Algebra Fraction Integer
- ^: (%, Integer) -> % if Expon has AbelianGroup and Coef has Field
from DivisionRing
- ^: (%, NonNegativeInteger) -> %
from MagmaWithUnit
- ^: (%, PositiveInteger) -> %
from Magma
- annihilate?: (%, %) -> Boolean
from Rng
- antiCommutator: (%, %) -> %
- apply_taylor: (Stream Coef, %) -> %
apply_taylor(ts, s)
applies Taylor series with coefficientsts
tos
, that is computes infinite sumts
(0) +ts
(1)*s
+ts
(2)*s^2
+ … Note:s
must be of positive order
- approximate: (%, Expon) -> Coef if Coef has ^: (Coef, Expon) -> Coef and Coef has coerce: Symbol -> Coef
from UnivariatePowerSeriesCategory(Coef, Expon)
- associates?: (%, %) -> Boolean if Coef has IntegralDomain
from EntireRing
- associator: (%, %, %) -> %
from NonAssociativeRng
- center: % -> Coef
from UnivariatePowerSeriesCategory(Coef, Expon)
- characteristic: () -> NonNegativeInteger
from NonAssociativeRing
- charthRoot: % -> Union(%, failed) if Coef has CharacteristicNonZero
- coefficient: (%, Expon) -> Coef
from AbelianMonoidRing(Coef, Expon)
- coerce: % -> % if Coef has CommutativeRing
from Algebra %
- coerce: % -> OutputForm
from CoercibleTo OutputForm
- coerce: Coef -> % if Coef has CommutativeRing
from Algebra Coef
- coerce: Fraction Integer -> % if Coef has Algebra Fraction Integer
- coerce: Integer -> %
from NonAssociativeRing
- commutator: (%, %) -> %
from NonAssociativeRng
- complete: % -> %
from PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
- construct: List Record(k: Expon, c: Coef) -> %
from IndexedProductCategory(Coef, Expon)
- constructOrdered: List Record(k: Expon, c: Coef) -> %
from IndexedProductCategory(Coef, Expon)
- D: % -> % if Coef has *: (Expon, Coef) -> Coef
from DifferentialRing
- D: (%, List Symbol) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- D: (%, List Symbol, List NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- D: (%, NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef
from DifferentialRing
- D: (%, Symbol) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- D: (%, Symbol, NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- degree: % -> Expon
from PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
- differentiate: % -> % if Coef has *: (Expon, Coef) -> Coef
from DifferentialRing
- differentiate: (%, List Symbol) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- differentiate: (%, List Symbol, List NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- differentiate: (%, NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef
from DifferentialRing
- differentiate: (%, Symbol) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- differentiate: (%, Symbol, NonNegativeInteger) -> % if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
- divide: (%, %) -> Record(quotient: %, remainder: %) if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- elt: (%, %) -> %
from Eltable(%, %)
- elt: (%, Expon) -> Coef
from UnivariatePowerSeriesCategory(Coef, Expon)
- euclideanSize: % -> NonNegativeInteger if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- eval: (%, Coef) -> Stream Coef if Coef has ^: (Coef, Expon) -> Coef
from UnivariatePowerSeriesCategory(Coef, Expon)
- expressIdealMember: (List %, %) -> Union(List %, failed) if Expon has AbelianGroup and Coef has Field
from PrincipalIdealDomain
- exquo: (%, %) -> Union(%, failed) if Coef has IntegralDomain
from EntireRing
- extend: (%, Expon) -> %
from UnivariatePowerSeriesCategory(Coef, Expon)
- extendedEuclidean: (%, %) -> Record(coef1: %, coef2: %, generator: %) if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- extendedEuclidean: (%, %, %) -> Union(Record(coef1: %, coef2: %), failed) if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- factor: % -> Factored % if Expon has AbelianGroup and Coef has Field
- gcd: (%, %) -> % if Expon has AbelianGroup and Coef has Field
from GcdDomain
- gcd: List % -> % if Expon has AbelianGroup and Coef has Field
from GcdDomain
- gcdPolynomial: (SparseUnivariatePolynomial %, SparseUnivariatePolynomial %) -> SparseUnivariatePolynomial % if Expon has AbelianGroup and Coef has Field
from GcdDomain
- infsum: Stream % -> %
infsum(x)
computes sum of all elements ofx
. Degrees of elements ofx
must be nondecreasing and tend to infinity.
- inv: % -> % if Expon has AbelianGroup and Coef has Field
from DivisionRing
- latex: % -> String
from SetCategory
- lcm: (%, %) -> % if Expon has AbelianGroup and Coef has Field
from GcdDomain
- lcm: List % -> % if Expon has AbelianGroup and Coef has Field
from GcdDomain
- lcmCoef: (%, %) -> Record(llcm_res: %, coeff1: %, coeff2: %) if Expon has AbelianGroup and Coef has Field
from LeftOreRing
- leadingCoefficient: % -> Coef
from PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
- leadingMonomial: % -> %
from PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
- leadingSupport: % -> Expon
from IndexedProductCategory(Coef, Expon)
- leadingTerm: % -> Record(k: Expon, c: Coef)
from IndexedProductCategory(Coef, Expon)
- leftPower: (%, NonNegativeInteger) -> %
from MagmaWithUnit
- leftPower: (%, PositiveInteger) -> %
from Magma
- leftRecip: % -> Union(%, failed)
from MagmaWithUnit
- map: (Coef -> Coef, %) -> %
from IndexedProductCategory(Coef, Expon)
- monomial?: % -> Boolean
from IndexedProductCategory(Coef, Expon)
- monomial: (Coef, Expon) -> %
from IndexedProductCategory(Coef, Expon)
- multiEuclidean: (List %, %) -> Union(List %, failed) if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- multiplyExponents: (%, PositiveInteger) -> %
from UnivariatePowerSeriesCategory(Coef, Expon)
- one?: % -> Boolean
from MagmaWithUnit
- opposite?: (%, %) -> Boolean
from AbelianMonoid
- order: % -> Expon
from UnivariatePowerSeriesCategory(Coef, Expon)
- order: (%, Expon) -> Expon
from UnivariatePowerSeriesCategory(Coef, Expon)
- plenaryPower: (%, PositiveInteger) -> % if Coef has Algebra Fraction Integer or Coef has CommutativeRing
- pole?: % -> Boolean
from PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
- prime?: % -> Boolean if Expon has AbelianGroup and Coef has Field
- principalIdeal: List % -> Record(coef: List %, generator: %) if Expon has AbelianGroup and Coef has Field
from PrincipalIdealDomain
- quo: (%, %) -> % if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- recip: % -> Union(%, failed)
from MagmaWithUnit
- reductum: % -> %
from IndexedProductCategory(Coef, Expon)
- rem: (%, %) -> % if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- removeZeros: (%, Expon) -> %
removeZeros(s, k)
removes leading zero terms ins
with exponent smaller thank
- rightPower: (%, NonNegativeInteger) -> %
from MagmaWithUnit
- rightPower: (%, PositiveInteger) -> %
from Magma
- rightRecip: % -> Union(%, failed)
from MagmaWithUnit
- sample: %
from AbelianMonoid
- sizeLess?: (%, %) -> Boolean if Expon has AbelianGroup and Coef has Field
from EuclideanDomain
- squareFree: % -> Factored % if Expon has AbelianGroup and Coef has Field
- squareFreePart: % -> % if Expon has AbelianGroup and Coef has Field
- subtractIfCan: (%, %) -> Union(%, failed)
- terms: % -> Stream Record(k: Expon, c: Coef)
from UnivariatePowerSeriesCategory(Coef, Expon)
- truncate: (%, Expon) -> %
from UnivariatePowerSeriesCategory(Coef, Expon)
- truncate: (%, Expon, Expon) -> %
from UnivariatePowerSeriesCategory(Coef, Expon)
- unit?: % -> Boolean if Coef has IntegralDomain
from EntireRing
- unitCanonical: % -> % if Coef has IntegralDomain
from EntireRing
- unitNormal: % -> Record(unit: %, canonical: %, associate: %) if Coef has IntegralDomain
from EntireRing
- variable: % -> Symbol
from UnivariatePowerSeriesCategory(Coef, Expon)
- zero?: % -> Boolean
from AbelianMonoid
AbelianMonoidRing(Coef, Expon)
Algebra % if Coef has CommutativeRing
Algebra Coef if Coef has CommutativeRing
Algebra Fraction Integer if Coef has Algebra Fraction Integer
ArcHyperbolicFunctionCategory if Coef has Algebra Fraction Integer
ArcTrigonometricFunctionCategory if Coef has Algebra Fraction Integer
BiModule(%, %)
BiModule(Coef, Coef)
BiModule(Fraction Integer, Fraction Integer) if Coef has Algebra Fraction Integer
canonicalsClosed if Expon has AbelianGroup and Coef has Field
canonicalUnitNormal if Expon has AbelianGroup and Coef has Field
CharacteristicNonZero if Coef has CharacteristicNonZero
CharacteristicZero if Coef has CharacteristicZero
CommutativeRing if Coef has CommutativeRing
CommutativeStar if Coef has CommutativeRing
DifferentialRing if Coef has *: (Expon, Coef) -> Coef
DivisionRing if Expon has AbelianGroup and Coef has Field
ElementaryFunctionCategory if Coef has Algebra Fraction Integer
Eltable(%, %)
EntireRing if Coef has IntegralDomain
EuclideanDomain if Expon has AbelianGroup and Coef has Field
Field if Expon has AbelianGroup and Coef has Field
GcdDomain if Expon has AbelianGroup and Coef has Field
HyperbolicFunctionCategory if Coef has Algebra Fraction Integer
IndexedProductCategory(Coef, Expon)
IntegralDomain if Coef has IntegralDomain
LeftModule Coef
LeftModule Fraction Integer if Coef has Algebra Fraction Integer
LeftOreRing if Expon has AbelianGroup and Coef has Field
Module % if Coef has CommutativeRing
Module Coef if Coef has CommutativeRing
Module Fraction Integer if Coef has Algebra Fraction Integer
NonAssociativeAlgebra % if Coef has CommutativeRing
NonAssociativeAlgebra Coef if Coef has CommutativeRing
NonAssociativeAlgebra Fraction Integer if Coef has Algebra Fraction Integer
noZeroDivisors if Coef has IntegralDomain
PartialDifferentialRing Symbol if Coef has *: (Expon, Coef) -> Coef and Coef has PartialDifferentialRing Symbol
PowerSeriesCategory(Coef, Expon, SingletonAsOrderedSet)
PrincipalIdealDomain if Expon has AbelianGroup and Coef has Field
RightModule Coef
RightModule Fraction Integer if Coef has Algebra Fraction Integer
TranscendentalFunctionCategory if Coef has Algebra Fraction Integer
TrigonometricFunctionCategory if Coef has Algebra Fraction Integer
TwoSidedRecip if Coef has CommutativeRing
UniqueFactorizationDomain if Expon has AbelianGroup and Coef has Field
UnivariatePowerSeriesCategory(Coef, Expon)